The subject matter described relates to traction rod assemblies and methods of vehicle systems.
Bogies of vehicle systems include one or more traction bars or radial arms that structurally support suspension systems of the bogies. For example, a traction bar or arm may allow vehicle wheels to move vertically with respect to the body of the bogie while reducing an amount of movement of the wheels in forward and/or backwards directions (e.g., longitudinally), or side to side (e.g., laterally) relative to the frame of the bogie.
Coupling the frame end of each radial arm with the bottom side of the frame, however, limits the overall height of the frame of the bogie system, and respectively, any cargo that the bogie may be carrying. For example, the bottom side of the frame must be disposed a distance away from a route (not shown) so as to provide enough clearance for the radial arms to be fixed to the bottom side of the frame. As the overall height of the bogie system increases, the stability of the bogie decreases as the bogie moves along the route.
It may be desirable to have a system and method that differs from those that are currently available.
In one or more embodiments, a traction rod assembly for a bogie system includes a body extending between a first end and a second end, and a bearing assembly coupled with the second end of the body. The bearing assembly includes cylindrical bearings and one or more spacers disposed between the cylindrical bearings along a bearing axis. The cylindrical bearings and the one or more spaces are concentric with a passage disposed at the second end of the body along the bearing axis. The first end of the body is coupled with a frame of the bogie system, and the bearing assembly is coupled with an axle assembly of the bogie system. The body is configured to rotate about the bearing axis relative to the axle assembly of the bogie system.
In one or more embodiments, a traction rod assembly for a bogie system includes a body extending between a first end and a second end, and a bush assembly operably coupled with the first end of the body. The bush assembly includes a first component having a passage extending between a first surface and a second surface of the first component, and a second component disposed within the passage of the first component. The bush assembly includes an eccentric offset such that a center of the first component is offset from a center of the second component.
In one or more embodiments, a traction rod assembly for a bogie system includes a body extending between a first end and a second end. A bush assembly is operably coupled with the first end of the body. The bush assembly includes a first component having a passage extending between a first surface and a second surface of the first component, and a second component disposed within the passage of the first component. The bush assembly includes an eccentric offset such that a center of the first component is offset from a center of the second component. A bearing assembly is operably coupled with the second end of the body. The bearing assembly includes cylindrical bearings and one or more spacers disposed along a bearing axis. The cylindrical bearings and the one or more spacers are concentric with a passage disposed at the second end of the body along the bearing axis. The bush assembly is operably coupled with a frame of the bogie system and the bearing assembly is operably coupled with an axle assembly of the bogie system. The bearing assembly allows rotation of the body relative to the axle assembly of the bogie system.
The inventive subject matter may be understood from reading the following description of non-limiting embodiments, with reference to the attached drawings, wherein below:
Embodiments of the subject matter described herein relate to traction rod assemblies and methods that may be used with bogie and/or vehicle systems. The traction rod assemblies may include a body that extends between a first end and a second end. The first end may be operably coupled with a frame of the bogie, and the second end may be operably coupled with an axle assembly of the bogie. In one embodiment, the second end may be operably coupled with an axle box of the axle assembly. Optionally, the first end of the traction rod assembly may be coupled with a component of the bogie other than the frame, and/or the second end of the traction rod assembly may be coupled with a component other than the axle box of the axle assembly.
In one or more embodiments, a bush assembly may be coupled with and/or disposed at the first end of the body. The bush assembly may also be referred to herein as a metal elastic bush or metal elastic bush assembly. For example, the bush assembly may include one or more metallic components and one or more elastomeric components coupled with the one or more metallic components. The elastomeric component of the bush assembly may move in one or more directions responsive to the first end of the traction rod assembly being coupled with the bogie system. For example, a length of the traction rod assembly may move and/or be adjusted based on movement of the elastomeric component and an eccentric offset of the bush assembly.
In one or more embodiments, a bearing assembly may be coupled with and/or disposed at the second end of the body. The bearing assembly may include cylindrical bearings that may receive a feature or portion of the axle assembly of the bogie system. As one example, the cylindrical bearings may receive a feature of the axle box of the axle assembly. The cylindrical bearings may allow rotation of the body of the traction rod assembly relative to the axle assembly of the bogie system. An outer race of each of the cylindrical bearings are allowed to rotate while an inner race of each of the cylindrical bearings remains fixed with the axle box. For example, the outer race of the cylindrical bearings may allow the body of the traction rod assembly to rotate responsive to a load being applied to the frame of the bogie (e.g., cargo being loaded onto the bogie) or a load being removed from the frame (e.g., a cargo being unloaded from the bogie), while the stationary inner race of the bearings coupled with the portion of the axle box may reduce an amount of rotation of the axle box.
The traction rod assembly reduces an amount of longitudinal movement of the axle box of the axle assembly and/or of the frame (e.g., forward or backward movement of the axle box, such as in a direction of movement of the bogie) relative to a bogie that does not include a traction rod assembly coupled with the axle box and the frame. The traction rod assembly reduces an amount of lateral movement of the axle box and/or the frame (e.g., side to side movement of the axle box in a direction that is substantially perpendicular to the direction of movement of the bogie) relative to a bogie that does not include a traction rod assembly coupled with the axle box and the frame. The traction rod assembly reduces an amount of vertical movement of the axle box and/or the frame (e.g., up and down movement of the axle box in a direction that is substantially perpendicular to the direction of movement of the bogie) relative to a bogie that does not include a traction rod assembly coupled with the axle box and the frame
In one or more embodiments, the bogie system may include plural traction rod assemblies. For example, the bogie system may include a number of traction rod assemblies and a same number of wheels that are operably coupled with the bogie system. Alternatively, the bogie system may include a number of traction rod assemblies and a same number of axles of the bogie system. Optionally, the bogie system may include any number of traction rod assemblies.
In one or more embodiments, one or more of the traction rod assemblies may include a bearing assembly but may not include a bush assembly. Additionally or alternatively, one or more of the traction rod assemblies may include a bush assembly but may not include a bearing assembly. For example, a bogie system may include one traction rod assembly that includes a bearing assembly but does not include a bush assembly, and another traction rod assembly that includes a bush assembly but does not include a bearing assembly. Optionally, the bogie system may include one or more traction rod assemblies each having the same and/or different configurations relative to each other.
One or more embodiments of the inventive subject matter may relate to bogies systems that may be used with rail vehicle systems, or other types or models of vehicle systems, such as automobiles, trucks, buses, mining vehicles, agricultural vehicles, other off-highway vehicles, or any other moving system that includes a suspension system.
The first axle is operably coupled with an axle box 126A of the axle assembly proximate the first side of the bogie system and is operably coupled with an axle box 126B of the axle assembly proximate the second side of the bogie system. Additionally, the second axle is operably coupled with an axle box 128A proximate the first side of the bogie system and is operably coupled with an axle box 128B proximate the second side of the bogie system.
The bogie system includes a frame 102 that includes plural surfaces that extend in one or more different directions. For example, the frame separates and/or provides a level of protection to a suspension system of the bogie system from what may be disposed on top of the frame (e.g., cargo, a vehicle frame, or the like). A first side 102A of the frame extends between about the front end and about the rear end of the bogie system and extends over a top side of the axle boxes 126A, 128A. A second side 102B of the frame extends between about the front end and about the rear end of the bogie system, and extends over a top side of the axle boxes 126B, 128B. A portion 170 of the frame (shown in
The bogie system includes one or more traction rod assemblies 120. In the illustrated embodiment of
The first and second ends of the traction rod assemblies are fixed to the frame and the corresponding axle box, respectively, such that the traction rod assemblies reduce an amount of movement of the axle boxes relative to a bogie system that does not include a traction rod assembly. Optionally, the traction rod assemblies may be fixed to another feature or component of the axle assembly of the bogie system. The traction rod assemblies reduce an amount of movement of the axle boxes in a vertical direction 202 (e.g., up and down), reduce an amount of movement of the axle boxes in a longitudinal direction 204 (e.g., forward and backward), and reduce an amount of movement of the axle boxes in a lateral direction 206 (e.g., side and side), relative to a bogie system that does not include a traction rod assembly. For example, the traction rod assemblies increase an amount of rigidity of the bogie system relative to a bogie system that does not include a traction rod assembly.
In one or more embodiments, the bogie system may include a connecting link 122. In the illustrated embodiment of
The second side linkage system including the first and second traction rod assemblies and the connecting link disposed on the second side of the bogie system is positioned outside of the frame of the bogie system. For example, the wheels 116B and 118B disposed on the second side of the bogie system are positioned between the second side linkage system and the wheels 116A, 118A disposed on the first side of the bogie system in the lateral direction 206.
In one or more embodiments, the first side of the bogie system (not shown in
The first end 130 of the body has a first end body 148 that has a substantially circular cross-sectional shape about an axis 182 and is elongated along the axis between first and second surfaces 176, 178. The first end body includes an opening or passage 150 that extends along the axis between the first and second surfaces. The second end 132 of the body has a second end body 190 that has a substantially circular cross-sectional shape about a bearing axis 180 and is elongated along the bearing axis between first and second surfaces 186, 188. The second end body includes an opening or passage 152 that extends along the bearing axis between the first and second surfaces. In the illustrated embodiment of
The passage 150 of the first end body receives a bush assembly 154. The bush assembly extends between a first end 192 and a second end 194. The first end may be substantially flush with the first surface 176 of the first end body, and the second end may be substantially flush with the second surface 178 of the first end body when the bush assembly is positioned within the passage 150. Alternatively, one or both of the first end or second ends of the bush assembly may not be substantially flush with the first or second surfaces, respectively.
In one or more embodiments, the bush assembly may be referred to as a metal elastic bush assembly, a metal bush assembly, a metal elastic bush, or the like. For example, the first component may be manufactured of a metal alloy, a metallic engineered material, a composite material, or the like. In one or more embodiments, the first component may be manufactured out of the same or a common material as the body of the traction rod assembly. The first component may also be referred to as a metal component, metal piece, metal structure, or the like. Optionally, the first component may be manufactured of an alternative material. The third component may be manufactured of a metal or metallic alloy, that may have a chemical composition that is the same or different than a chemical composition of the material of the first component. The third component may also be referred to as a mating component, mating structure of the bush assembly, or the like. For example, the mating or third component is configured to be operably coupled with a portion of the frame of the bogie system.
The second component may be manufactured of an elastomer, that is, of an elastomeric material. Examples of elastomeric materials may include natural and/or synthetic rubber. Optionally, the second component may be manufactured of a polymer material such as, but not limited to, a low and/or high density polyethylene, polypropylene, polyvinyl chloride (PCV), nylon, Teflon, a thermoplastic polyurethane material, or the like. In one or more embodiments, the design, configuration, orientation, shape, size, or the like, of the second component may be adjusted to tune the longitudinal and/or lateral characteristics of the suspension of the bush assembly based on the material used to form the second component. In one embodiment, the elastic material may be a conductive elastic material, or alternatively may be a non-conductive material. The second component may be referred to herein as an elastomer component, a rubber component, a flexible structure, or the like. In one embodiment, the material composition of the first component and the material composition of the third component have stiffnesses may be greater than a stiffness of the material composition of the second component. For example, the second component is configured to flex or move, and the first and third components are configured to remain substantially stationary, fixed, or unmoved.
The first component extends between a first surface (not visible in
In one or more embodiments, the first surfaces of two or more of the first, second, or third components may be substantially planar with each other. Additionally or alternatively, the second surfaces of two or more of the first, second, or third components may be substantially planar with each other. In one or more embodiments, the first and/or second surfaces of one or more of the first, second, or third components may include one or more radii, curves, chamfers, or the like. For example, in the illustrated embodiment of
The bush assembly includes an eccentric offset 324 such that the first center axis 320 of the first component is offset from the second center axis 322 of the second and third components. In one or more embodiments, the eccentric offset may be a distance that is about 1 millimeter (mm), about 3 mm, about 5 mm, about 10 mm, or the like. The eccentric offset enables the elastomeric or second component of the bush assembly to move in one or more directions responsive to the first end of the traction rod assembly being coupled with the bogie system. For example, a length of the traction rod assembly may move and/or be adjusted based on movement of the second component and the eccentric offset of the bush assembly. The eccentric offset allows the traction rod assembly to be more accurately positioned when the traction rod assembly is coupled with the bogie system relative to a bush assembly not including an eccentric offset. Additionally, the eccentric offset increases a design tolerance (e.g., makes less restrictive) of the traction rod assembly relative to a traction rod assembly not including a bush assembly having an eccentric offset.
Returning to
The assembly system shown in
As the bogie system operates with the first end of the traction rod assembly coupled with the frame, the second component (e.g., the elastomeric component) of the bush assembly flexes or moves relative to the first component (e.g., the metallic component). For example, a stiffness of the elastomeric material that is used to manufacture the second component controls an amount of movement of the first end of the traction rod assembly relative the frame. In one or more embodiments, the stiffness of the second component may control a rigidity of the bogie system, such as when the bogie system is moving along a route, when cargo is loaded and/or unloaded onto the bogie system, when the bogie system changes a propulsion and/or braking operation, or the like. For example, the material properties, including the stiffness of the elastomeric material of the second component, may control a smoothness of the bogie system as the bogie system moves along the route. For example, the second component may flex and/or move to dampen one or more movements of the frame relative to the axle box of the bogie system.
Returning to
The bearing assembly including the cylindrical bearings and the spacers may be assembled within the passage of the second end of the body by inserting the bearing assembly into the passage from the second surface 188 of the second end and moving the bearing assembly in a direction toward the first surface 186 of the second end along the bearing axis. The bearing assembly may be maintained within the passage via one or more assembly components 162 and/or one or more assembly fasteners 164. For example, in the illustrated embodiment of
The illustrated embodiment of the traction rod assembly shown in
In the illustrated embodiment, a first assembly component 910, a second assembly component 920, and a bolt 944 are used to couple the second end of the traction rod assembly with the axle box. The first assembly component includes a first end 916 that is received within an axle box body pocket 932 of an axle box body 930. In the illustrated embodiment, the first end and the axle box body pocket have corresponding threads to couple the first assembly component with the axle box body. The first assembly component also includes a second end 918 that is received within a passage of the bearing assembly. The first assembly component includes a lip 922 that separates the first end from the second end, controls an amount of movement of the first assembly component in the first direction A, and controls an amount of movement of the second end of the traction rod assembly in the first direction A.
The second assembly component 920 is directed into the passage of the bearing assembly in the first direction A, and is configured to mate with the second spacer 160B within the passage. In the illustrated embodiment, the second assembly component extends a distance beyond the second surface 188 of the second end of the body. Alternatively, the second assembly component may have an alternative shape and/or size, may be substantially flush with the second surface, or any combination therein. In the illustrated embodiment, a portion of the second end of the first assembly component extends within a passage of the second assembly component. The second assembly component and the second end of the first assembly component receive the bolt 944 that couples the second end of the traction rod assembly with the axle box of the bogie system. Optionally, the second end of the traction rod assembly may be operably coupled with the axle box of the bogie system via an alternative assembly method and one or more alternative assembly components.
The cylindrical bearings may allow rotation of the body of the traction rod assembly relative to the axle box of the bogie system. For example, an outer race of each of the cylindrical bearings is allowed to rotate while an inner race of each of the cylindrical bearings remains fixed. For example, the outer race of the cylindrical bearings may allow the body of the traction rod assembly to rotate responsive to a load being applied to the frame of the bogie (e.g., cargo being loaded onto the bogie) or a load being removed from the frame (e.g., a cargo being unloaded from the bogie), while the stationary inner race of the cylindrical bearings coupled with the portion of the axle box via the assembly components may reduce an amount of rotation of the axle box.
In one or more embodiments of the subject matter described herein, a traction rod assembly for a bogie system includes a body extending between a first end and a second end, and a bearing assembly coupled with the second end of the body. The bearing assembly includes cylindrical bearings and one or more spacers disposed between the cylindrical bearings along a bearing axis. The cylindrical bearings and the one or more spaces are concentric with a passage disposed at the second end of the body along the bearing axis. The first end of the body is coupled with a frame of the bogie system, and the bearing assembly is coupled with an axle box of the bogie system. The body is configured to rotate about the bearing axis relative to the axle box of the bogie system.
Optionally, the traction rod assembly may include a bush assembly operably coupled with the first end of the body. The bush assembly may include a first component having a passage extending between a first surface and a second surface of the first component, and a second component disposed within the passage of the first component. The bush assembly may include an eccentric offset such that a center of the first component is offset from a center of the second component.
Optionally, the first component may be manufactured of a metallic material, and the second component may be manufactured of an elastomeric material.
Optionally, the bush assembly may include a third component disposed within a passage of the second component that extends between a first surface and a second surface of the second component. The third component may include a mating interface that is configured to be coupled with a mating component of the frame of the bogie system.
In one or more embodiments, a bogie system may include a bush assembly and a bearing assembly. The bush assembly may be coupled with the frame of the bogie system. The traction rod assembly may reduce an amount of translational movement of the axle box of the bogie system relative to the bush assembly not being coupled with the frame and the bearing assembly not being coupled with the axle box of the bogie system.
Optionally, the bearing assembly and the bush assembly may increase a level of rigidity of the bogie system relative to the first end not being coupled with the frame of the bogie system and the second end of the body not being coupled with the axle box of the bogie system.
Optionally, the traction rod assembly may be a first traction rod assembly, and the bogie system may include plural traction rod assemblies. The first traction rod assembly and a second traction rod assembly may be disposed on a first side of the bogie system, and a third traction rod assembly and a fourth traction rod assembly may be disposed on a second side of the bogie system.
Optionally, the first and second traction rod assemblies may be disposed on the first side of the bogie system at a position outside of the frame of the bogie system, and the third and fourth traction rod assemblies may be disposed on a second side of the bogie system at a position outside of the frame of the bogie system.
In one or more embodiments of the subject matter described herein, a traction rod assembly for a bogie system includes a body extending between a first end and a second end, and a bush assembly operably coupled with the first end of the body. The bush assembly includes a first component having a passage extending between a first surface and a second surface of the first component, and a second component disposed within the passage of the first component. The bush assembly includes an eccentric offset such that a center of the first component is offset from a center of the second component.
Optionally, the bush assembly may be operably coupled with a mating component. A mating axis of the mating component may be offset from the center of the first component and the mating axis of the mating component may be aligned with the center of the second component.
Optionally, the first component may be manufactured of a metallic material and the second component may be manufactured of an elastomeric material.
Optionally, the bush assembly may include a third component disposed within a passage of the second component that extends between a first surface and a second surface of the second component. The third component may include a mating interface that is to be coupled with a mating component of a frame of the bogie system.
Optionally, the traction rod assembly may include a bearing assembly operably coupled with second end of the body. The bearing assembly may include cylindrical bearings and one or more spacers disposed along a bearing axis. The cylindrical bearings and the one or more spacers are concentric with a passage disposed at the second end of the body along the bearing axis. The bearing assembly may be coupled with an axle box of the bogie system and may allow rotation of the body relative to the axle box of the bogie system.
Optionally, the bush assembly may be coupled with a frame of the bogie system.
Optionally, the bearing assembly may allow rotation of the body relative to the axle box of the bogie system, and the bearing assembly and the bush assembly may reduce an amount of translational movement of the axle box relative to the bush assembly not being coupled with the frame of the bogie system and the bearing assembly not being coupled with the axle box of the bogie system.
Optionally, the bearing assembly and the bush assembly may increase a level of rigidity of the bogie system relative to the first end of the body not being coupled with the frame of the bogie system and the second end not being coupled with the axle box of the bogie system.
Optionally, the first end of the body may be operably coupled with a frame of the bogie system and the second end of the body may be operably coupled with an axle box of the bogie system.
In one or more embodiments of the subject matter described herein, a traction rod assembly for a bogie system includes a body extending between a first end and a second end. A bush assembly is operably coupled with the first end of the body. The bush assembly includes a first component having a passage extending between a first surface and a second surface of the first component, and a second component disposed within the passage of the first component. The bush assembly includes an eccentric offset such that a center of the first component is offset from a center of the second component. A bearing assembly is operably coupled with the second end of the body. The bearing assembly includes cylindrical bearings and one or more spacers disposed along a bearing axis. The cylindrical bearings and the one or more spacers are concentric with a passage disposed at the second end of the body along the bearing axis. The bush assembly is operably coupled with a frame of the bogie system and the bearing assembly is operably coupled with an axle box of the bogie system. The bearing assembly allows rotation of the body relative to the axle box of the bogie system.
Optionally, the first component of the bush assembly may be manufactured of a metallic material and the second component of the bush assembly may be manufactured of an elastomeric material.
Optionally, the bearing assembly may allow rotation of the body relative to the axle box of the bogie system, and the bearing assembly and the bush assembly may reduce an amount of translational movement of the axle box relative to the bush assembly not being couple with the frame of the bogie system and the bearing assembly not being coupled with the axle box of the bogie system.
The singular forms “a”, “an”, and “the” include plural references unless the context clearly dictates otherwise. “Optional” or “optionally” means that the subsequently described event or circumstance may or may not occur, and that the description may include instances where the event occurs and instances where it does not. Approximating language, as used herein throughout the specification and claims, may be applied to modify any quantitative representation that could permissibly vary without resulting in a change in the basic function to which it may be related. Accordingly, a value modified by a term or terms, such as “about,” “substantially,” and “approximately,” may be not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value. Here and throughout the specification and claims, range limitations may be combined and/or interchanged, such ranges may be identified and include all the sub-ranges contained therein unless context or language indicates otherwise.
This written description uses examples to disclose the embodiments, including the best mode, and to enable a person of ordinary skill in the art to practice the embodiments, including making and using any devices or systems and performing any incorporated methods. The claims define the patentable scope of the disclosure, and include other examples that occur to those of ordinary skill in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
This application claims priority to U.S. Provisional Application No. 63/125,218, filed Dec. 14, 2020, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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63125218 | Dec 2020 | US |